智能内生网络中基于 preDQN 的 TAS 流量调度

IF 4 3区计算机科学 Q1 COMPUTER SCIENCE, INFORMATION SYSTEMS

IEEE Systems Journal Pub Date : 2024-03-30 DOI:10.1109/JSYST.2024.3402664

Baogang Li;Lu Chen;Zhi Yang;Hongyin Xiang

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引用次数: 0

摘要

时间敏感网络（TSN）工作组将时间感知形状（TAS）标准化，以减少网络延迟，但传统的 TAS 标准缺乏适应性，无法在动态变化的环境中发挥良好作用。不断发展的人工智能技术可以与 TSN 相结合，从而更好地适应动态变化的环境。因此，我们利用深度强化学习（DRL）算法对网络进行动态配置，以提高其适应性。同时，我们在 TAS 中提出了队列传输方法，为不同类型的流量加入传输窗口，使资源分配更简单、更高效。然而，DRL 算法通常需要大量时间来训练，这与 TAS 的延迟敏感性相悖。因此，我们提出了一种改进的 DRL 算法，称为 preDQN，其中网络预测用于帮助代理更有效地探索环境。我们在仿真环境中进行了实验验证，实验结果表明，该方案能显著提高资源利用率，降低端到端延迟和丢包率。

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preDQN-Based TAS Traffic Scheduling in Intelligence Endogenous Networks

The time-sensitive networking (TSN) working group standardizes time-aware shapes (TAS) to reduce network latency, but the traditional TAS standard lacks adaptability and cannot perform well in dynamically changing environments. The continuously developing artificial intelligence techniques can be combined with TSN to better adapt the dynamically changing environments. Therefore, we utilize deep reinforcement learning (DRL) algorithms to dynamically configure the network to improve its adaptability. Meanwhile, we propose the queuing transmission method in TAS by incorporating transmission windows for different types of traffic, to make resource allocation simpler and more efficient. However, DRL algorithms usually take a lot of time to train, which is contrary to the delay sensitivity of TAS. Hence, we propose an improved DRL algorithm, called preDQN, where the network prediction is used to help the agent explore the environment more efficiently. Experimental validation is carried out in a simulation environment, and the experimental results show that the scheme can significantly improve the resource utilization, reduce the end-to-end delay and packet loss rate.

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来源期刊

IEEE Systems Journal 工程技术-电信学

CiteScore

9.80

自引率

6.80%

发文量

572

审稿时长

4.9 months

期刊介绍： This publication provides a systems-level, focused forum for application-oriented manuscripts that address complex systems and system-of-systems of national and global significance. It intends to encourage and facilitate cooperation and interaction among IEEE Societies with systems-level and systems engineering interest, and to attract non-IEEE contributors and readers from around the globe. Our IEEE Systems Council job is to address issues in new ways that are not solvable in the domains of the existing IEEE or other societies or global organizations. These problems do not fit within traditional hierarchical boundaries. For example, disaster response such as that triggered by Hurricane Katrina, tsunamis, or current volcanic eruptions is not solvable by pure engineering solutions. We need to think about changing and enlarging the paradigm to include systems issues.